phylogeography, species delimitation and an analysis of ... · of the complexity of the...
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UNIVERSIDADE FEDERAL DE MINAS GERAIS
INSTITUTO DE CIÊNCIAS BIOLÓGICAS
Samuel Chagas Bernardes
The evolutionary history of Caridina typus:
phylogeography, species delimitation and an analysis
of the complexity of the Indo-Pacific biogeography
Belo Horizonte – MG
2018
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Samuel Chagas Bernardes
The evolutionary history of Caridina typus:
phylogeography, species delimitation and an analysis of
the complexity of the Indo-Pacific biogeography
Dissertação apresentada ao Programa de Pós-
graduação em Zoologia do Instituto de
Ciências Biológicas da Universidade Federal
de Minas Gerais como requisito parcial para
obtenção do grau de Mestre em Zoologia –
Área de concentração em
Orientador: Almir Rogério Pepato
Belo Horizonte – MG
2018
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ACKNOWLEDGMENTS
My most sincere thanks:
- to my advisor, Almir Pepato, whose support, both personal and professional, was priceless
through this project;
- to Mark de Bruyn, who has conceded me autonomy to conduct this project when I was still
an undergraduate and an exchange student in the Bangor University and has indeed become a
major source of support and inspiration;
- to my fiancée, Maíra, who has been my main source of support and motivation ever since she
entered my life;
- to my brother, Raphael, who was regularly the only thing that took me away from the
computer to take a breath through all the work;
- to my intern in Bangor, Sarah Karpati, who has no idea of how important she was to my
progress;
- to the mentors I had through my academic journey who contributed at some point to my
formation: Adalberto, Almir, André, Bernadete, Fabrício, Fernando, Flávio, Gary, Gustavo,
Kat, Maria Amélia, Mário, Mark, Teofânia and Ubirajara;
- to the masters I’ve never met but who represent the shoulders of giants on which I stood to
see more and farther: Darwin, Wallace, Huxley, Avise, Dobzhansky, Fisher, Gould, Nei,
Kimura, Tajima, Felsenstein, Hennig, Haeckel, Haldane, Maynard Smith, Kingman, Platnick,
Nelson among many others;
- to the CNPq for the investment, both during the travel that originated the project (Science
Without Borders) and during its execution in Brazil;
- to my friends: Adam, Camilla, Carol, Ênio, Larissa, Leonardo, Marco, Michael, Pedro,
Raphael, Yasmim and Zoe, and why not include Almir and Mark, who have become great
friends, and Maíra, who is my friend for life.
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“We are like dwarves perched on the shoulders of giants, and thus we are able to see more
and farther than the latter.”
- Isaac Newton
“(...) The ascent of man is not made by lovable people. It is made by people who have two
qualities: an immense integrity, and at least a little genius.”
- Jacob Bronowski
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RESUMO
O Oceano Índico inclui em sua área de influência nove hotspots de biodiversidade,
incluindo alguns dos mais icônicos (e, portanto, mais estudados) centros de endemismo do
mundo. Historicamente, a região tem servido como um prolífico laboratório de estudos
geológicos e biogeográficos e, avaliando a distribuição da diversidade, nos foi possível inferir
sobre a história biológica da região e sobre os processos que a influenciam, especialmente, no
que diz respeito ao endemismo. O estudo de espécies não-marinhas com ampla distribuição
através do Oceano Índico como Caridina typus H. Milne-Edwards, 1837 pode esclarecer
muitos desses dilemas acerca da história recente dessa área e da dinâmica evolutiva de espécies
vágeis. O objetivo primário desse estudo é, portanto, a avaliação da história evolutiva das
populações de C. typus bem como a apuração de sua filogeografia e status taxonômico. Foram
amplificados cinco marcadores (dois mitocondriais e três nucleares) de 129 indivíduos ao longo
da região Indo-Pacífica (área de ocorrência da espécie). No capítulo 3 está a filogenia datada e
a inferência de uma história evolutiva para o complexo de espécies. Ainda nesse capítulo, é
sugerida a delimitação de três espécies dentro de C. typus feita através de três métodos
diferentes. Ao mostrar, pela primeira vez na literatura, um resultado consistente entre vários
métodos diferentes, faz-se também uma breve crítica sobre a delimitação de espécies baseada
em marcadores mitocondriais. Com base no cenário teórico em que essa pesquisa está inserida,
um segundo objetivo foi estabelecido: uma revisão e meta-análise de estudos biogeográficos
moleculares realizados na região do Oceano Índico. Esse oceano tem uma complexa história
geológica relacionada com a fragmentação de supercontinentes, paleo-oceanos e com a
travessia da Índia através dos hemisférios. No entanto, o estudo biogeográfico da região foi
mais influenciado pelas escolas de pensamento do que pela evidência real da biodiversidade.
Com o uso de novas metodologias associadas ao desenvolvimento da biologia molecular, pode-
se elucidar muitas das discussões a respeito das áreas de endemismo do Oceano Índico. No
capítulo 2 (organizado assim por motivos práticos), foi realizada uma extensiva revisão da
literatura acerca da história geológica e biológica da região e 7 trabalhos filogenéticos mais ou
menos geograficamente inclusivos foram reanalisados. Os resultados mostram que a história
biogeográfica da região é complexa e envolve diversos eventos de vicariância, dispersão (curta
e transoceânica) e que a área ainda tem muito a oferecer em termos de conhecimentos sobre
processos evolutivos.
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ABSTRACT
The Indian Ocean comprises nine hotspots of biodiversity in its area of influence,
including some of the world’s most iconic (and thus most studied) centres of endemism.
Historically, the area serves as a prolific laboratory for geologic and biogeographic studies and
by assessing the biodiversity distribution it became possible to infer about the biological history
of the region and the processes that influence it, particularly in what refers to endemism. The
study of non-marine species widely distributed across the Indian Ocean such as Caridina typus
H. Milne-Edwards, 1837 may shed some light on many of these dilemmas on the recent history
of this area and of the evolutionary dynamics of vagile species. The primary objective of this
study is, therefore, the investigation of the evolutionary history of the C. typus’ populations
and to canvass their relations and taxonomic status. Five molecular markers were amplified
(two mitochondrial and three nuclear) for 129 individuals across the Indo-Pacific region
(species’ area of occurrence). Caridina typus’ dated phylogeny can be found in chapter 3 with
an inference of the evolutionary history of the species complex. Still in chapter 3, three species
were suggested by delimitation methods in C. typus by three different methods. By showing,
for the first time in literature, an agreement between various methods, a brief critique on the
species delimitation based on mitochondrial markers was also made. Based on the theoretical
scenario in which this research is inserted, a second aim was established: a review and meta-
analysis of the biogeographical molecular studies done across the Indian Ocean. That ocean
has a complex geological history, intimately related to the fragmentation of supercontinentes,
paleo-oceans and the India’s drift through the hemispheres. However, biogeographic estudies
there have been more influenced by biogeographic schools than by real evidence from
biodiversity. With the new methods associated to the development of the molecular biology
one can elucidate a great part of the discussions on Indian Ocean’s areas of endemism. In
chapter 2 (organised this way due to practical reasons), the literature about the geological and
biological history of the region was extensively reviewed and 7 phylogenetic works more or
less geographically inclusive were re-analysed. The results show that the biogeographic history
of the region is complex and involves various events of vicariance, dispersal (both short and
long-distance) and that the area still has much to offer in terms of knowledge on evolutionary
processes.
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FIGURE LIST
Figure 1.1: Lateral view of an atyid highlighting the family’s particular features.
Figure 1.2: Distribution of the atyids and of the genus Caridina – and thus of Caridina typus.
Figure 2.1: Geological reconstruction of the Indian Ocean continents through the Mesozoic and
Cenozoic eras.
Figure 2.2: Ancestral area reconstruction and biogeographic history.
Figure 3.1: Sampling map of the Indo-Australian Archipelago (IAA) and Eastern Asia (a), with
detail for Philippine islands (b); Western Indian Ocean (c) and South Pacific (d).
Figure 3.2: Time-calibrated phylogenetic and phylogeographic relationships in Caridina typus
rooted using C. opaensis.
Figure 3.3: Mitochondrial 16S haplotype network.
Figure 3.4: Extended Bayesian skyline plot for mtDNA and multiloci data for each main clade
of Caridina typus.
Figure 3.5: An illustrated suggestion for the biogeographic history of Caridina typus.
Supplementary Figure S1: 28S alignment through secondary structure for the 18 haplotypes
represented in the network.
Supplementary Figure S2: Multispecies mitochondrial 16S Bayesian Caridina tree.
Supplementary Figure S3: Haplotype networks for all five markers.
Supplementary Figure S4: STACEY matrix.
Supplementary Figure S5: RASP’s BayArea full result.
Supplementary Figure S6: BEAST discrete phylogeography result with collapsed branches per
range.
Supplementary Figure S7: Partial COI (167 nucleotide) maximum likelihood and neighbour-
joining tree including Fujita et al.'s (2016) sequences.
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ABBREVIATION LIST
°C: Celsius degrees
ANM: Anonymous Nuclear Marker
bp: base pair
COI: Subunity I of the cytochrome c oxidase
DNA: Deoxyribonucleic acid
IAA: Indo-Australian Archipelago
K-Pg: Cretaceous–Paleogene
Ma: Mega annum (anna), i.e., Million(s) years
min: Minute(s)
MIOJet: Miocene Indian Ocean Equatorial Jet
mm: Millimetre(s)
OTU: Operational taxonomic unity(ies)
s: Second(s)
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CONTENTS
TITLE ........................................................................................................................................ I
ACKNOWLEDGMENTS ........................................................................................................ II
RESUMO ................................................................................................................................. VI
ABSTRACT ........................................................................................................................... VII
FIGURE LIST ....................................................................................................................... VIII
ABBREVIATION LIST .......................................................................................................... IX
CONTENTS .............................................................................................................................. X
Chapter 1: General introduction................................................................................................. 1
1.1 Taxonomy and evolution of the Atyidae (Decapoda: Caridea) ................................... 1
1.2 Molecular systematics and taxonomy ......................................................................... 3
1.3 Phylogeography and population genetics .................................................................... 4
1.4 Thesis justification and aims ....................................................................................... 5
Chapter 2: A brief review and analysis of the Indian Ocean biogeography – A highway for
continental species ................................................................................................................... 10
2.1 Abstract ..................................................................................................................... 10
2.2 Introduction ............................................................................................................... 10
2.3 Overview of the Indian Ocean’s geology .................................................................. 12
2.3.1 On the Eastern Indian Ocean ............................................................................. 15
2.3.2 On the Western Indian Ocean ............................................................................ 15
2.4 The Indian Ocean’s biogeography ............................................................................ 16
2.5 Materials and methods .............................................................................................. 20
2.5.1 Studies chosen .................................................................................................... 20
2.5.2 Phylogenetic analyses ........................................................................................ 21
2.5.3 Biogeographic analyses ..................................................................................... 24
2.6 Results ....................................................................................................................... 24
2.6.1 Ancient taxa diversification ............................................................................... 24
2.6.2 Volant taxa diversification ................................................................................. 27
2.6.4 Recent taxa diversification .................................................................................... 28
2.7 Discussion ................................................................................................................. 28
2.7.1 On an isolated India and its relationship with Seychelles and Madagascar ...... 28
2.7.2 On the colonisation of the Indian Ocean islands ............................................... 29
2.8 Conclusion ................................................................................................................. 31
Chapter 3: The complex evolutionary history and phylogeography of Caridina typus
(Crustacea: Decapoda): long-distance dispersal and cryptic allopatric speciation with
comments on species delimitation ........................................................................................... 32
3.1 Abstract ..................................................................................................................... 32
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3.2 Introduction ............................................................................................................... 33
3.2 Materials and methods .............................................................................................. 34
3.2.1 Sampling ............................................................................................................ 34
2.4.2 DNA – extraction, amplification and sequencing .............................................. 36
3.2.3 Phylogenetic analyses ........................................................................................ 36
3.2.4 Analyses with Datasets: priors and model setting ............................................. 37
3.2.5 Species delimitation analyses ............................................................................ 39
3.2.6 Demographic and phylogeographic analyses ..................................................... 39
3.3 Results ....................................................................................................................... 40
3.3.1 DNA – extraction, amplification and sequencing .............................................. 40
3.3.2 Phylogenetic analyses ........................................................................................ 40
3.3.3 Species delimitation analyses ............................................................................ 41
3.3.4 Demographic and phylogeographic analyses ..................................................... 44
3.4 Discussion ................................................................................................................. 47
3.5 Conclusion ................................................................................................................. 53
Bibliography ............................................................................................................................ 54
Appendix .................................................................................................................................. 77
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Chapter 1: General introduction
This is a work of phylogeography with comments on taxonomy. Phylogenetics and
population genetics are intrinsic to phylogeography as establishing the relations between and
inside populations is paramount to demonstrate a taxon’s macro and microevolutionary aspects.
Therefore, just as researches on phylogeography and population genetics frequently lead to
questioning and/or altering the current biological classification, the observations of the natural
populations made by taxonomists may suggest phylogeographic studies to assess their
connections.
Even though this study is about the use of genetic tools to infer a taxon’s distribution
history, molecular systematics is needed to study the past and trends in its current populations.
That makes it impossible to overlook a discussion on its taxonomic status. Also, this work
brings preliminary results of a review on biogeographic works accomplished through the Indian
Ocean area. Such review is important to evidence the main rules and processes involved with
the distribution patterns we find today.
1.1 Taxonomy and evolution of the Atyidae (Decapoda: Caridea)
The Atyidae are a family of freshwater shrimps found across all continents, but
Antarctica (Williams 1980). Their most obvious synapomorphy are the setae found on the tip
of the chelae of their maxillipeds; those are thin, hair-like, and are used to scrape food off the
substrate (Bruce 1992). Furthermore, the atyids can be characterised by the presence of a
supraorbital spine and exopods on the pereopods (which are uniramous among most Decapoda;
see fig. 1.1) (Williams 1980). Both molecular (Porter et al. 2005) and morphologic
(Felgenhauer & Abele 1985) data point to an early divergence of the family inside the Caridea.
Porter et al. (2005) suggest that the divergence between atyids and other Caridea happened at
some point in the Late Permian and the diversification within the family happened in the Early
Jurassic.
Atyids are usually smaller than 35 mm (with a few exceptions; see Chace 1983) and are
found in all types of freshwater bodies in addition to anchialine formations and caves, plus
some species show an estuarine reproduction (Davie 2002). There are no extant marine atyids
(Huxley 1880; Fryer 1977), but their life histories vary a lot according to the species or genus.
Such diversity seems to be intrinsic to the morphology of the egg (Jalihal et al. 1994; Hancock
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1998): small eggs indicate planktonic larvae with high tolerance to salinity (often belonging to
species with estuarine breeding), large eggs belong to species with direct development and low
tolerance to salinity and intermediate-sized eggs point out to species with transitional features
in both development and salinity tolerance (Hayashi & Hamano 1984; Hancock et al. 1998;
Shy et al. 2001; Fièvet & Eppe 2002; Short & Doumenq 2003).
Given their reduced size and abundance in freshwater environments, atyids have major
ecosystemic roles. First, as Yam and Dudgeon (2006) showed, species in the genus Caridina
H. Milne-Edwards, 1837 show a higher production rate if compared to similar crustaceans. In
addition, in the family are some of the most important algae (March & Pringle 2003) and
particulate matter consumers, whose absence may unbalance a system’s biomass and
sedimentation levels (Yam & Dudgeon 2005; de Souza & Moulton 2005). Besides, the atyids
are an importante prey in their ecosystems (Covich et al. 1999).
The biogeography of the Atyidae clearly involves both vicariance (given the family’s
age, older than most of the continental separation events) and dispersal (thanks to the diversity
in salinity tolerance and history of life) (Bănărescu 1990; von Rintelen et al. 2007, 2012). Also,
their classification is historically troublesome (Huxley 1880; Fryer 1977) and has been going
Figure 1.1: Lateral view of an atyid highlighting the family’s particular features
(adapted from Williams 1980)
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through many changes recently (e.g. Page et al. 2005; Porter et al. 2005; von Rintelen et al.
2012; Jurado-Rivera et al. 2016). Caridina is probably the most problematic genus:
taxonomically it has been largely neglected, with over 300 described species and dozens of
ambiguities (Fransen 2015); biogeographically, with species distributed across the
paleotropical and part of the palearctic regions (see fig. 1.2), it has been shown to have a very
complex and active history with multiple events of dispersal, vicariance and environmental
invasion (von Rintelen et al. 2012; Jurado-Rivera et al. 2017). The phylogeography and
taxonomic assessment of the Atyidae are thus particularly interesting to the evolutionary
dynamics of freshwater species.
1.2 Molecular systematics and taxonomy
Molecular systematics is the field of systematics that uses molecular data, mainly DNA
sequences, to clarify the evolutionary relations between the organisms and evaluate the current
taxonomy (Hillis et al. 1996). This branch arose in the 1960’s when the development of
techniques in molecular biology brought grandiose promises of resolution of the ‘tree of life’
(Zuckerkandl & Pauling 1965). Naturally, such promises found equally grandiose obstacles
and propelled methodological advances. It also inflamed philosophical discussions, which were
revived in the last decade with the emergence of the Barcode of Life project, an attempt to
reduce species identification to a DNA analysis (Hebert et al. 2003).
Figure 1.2: Distribution of the atyids and of the genus Caridina – and thus of Caridina typus.
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One of the main concerns of the Barcode project is the identification of cryptical species
– i. e., two or more species that have been historically described under a single scientific name
due to morphological indistinguishability (Bickford et al. 2006) –, which is problematic with a
morphological approach (Hebert et al. 2003). Thereby, the Barcode brought new promises and
expectations on the use of the molecular data (Blaxter 2003; Proudlove & Wood 2003;
reviewed by Bickford et al. 2006), but the debate on how to assess the taxonomic status of new
genetically determined ‘species’ is still a hot topic due to favouritism of one or other method
(Dunn 2003; Hebert et al. 2003; Lipscomb et al. 2003; Scotland et al. 2003; Tautz et al. 2003;
Blaxter 2004). To assess each morphologic and molecular method’s pros and cons generated
debates in both systematics and conservation (ex. Daugherty et al. 1990; Geller 1999; Hay et
al. 2010) as well as in the way that we understand old and new types of data (ex. Will &
Rubinoff 2004; Collins & Cruickshank 2014).
This scenario created a demand for methods that allowed the evaluation of molecular
phylogenies in order to delimit ‘species’ or operational taxonomic unities (OTU) especially for
modest datasets based on the Barcode approach (Carstens et al. 2013). Some of these methods,
essentially linked to the Barcode, require no more than one locus (ex. Fujisawa & Barraclough
2013). There are a considerable number of methods nowadays and they may be easily
compared as they deal with different evolutionary problems, properties and concepts (Carstens
et al. 2013; Satler et al. 2013; see de Queiroz 2007). Carstens et al. (2013) evidenced that many
studies present incongruences between different methods and justify them by showing how the
methods’ premises were violated. Consequently, the authors propose that to make use of
several methods and assess their concordance is a good way to deal with delimitation.
1.3 Phylogeography and population genetics
Ortmann (1994) asserted that to establish the relations and affinities between taxa is
primary to understand and find out the causes for the geographical distribution. The author is
referring to the identification and classification of species that have a wide distribution and are
often recognised as cryptical species (Bohonak & Jenkins 2003) or as result of homoplasy
(Bossuyt et al. 2004). Biogeographical research and hypotheses are inherent to the phylogeny
as the reconstruction of the relationships between populations raises and addresses questions
about the framework related to them (Emerson 2002). It means that scenarios where the
taxonomy is not directly connected to the phylogeny can (and frequently will) lead
biogeographical studies to major mistakes or, at least, to dead ends in the understanding.
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While phylogeny has been associated to historical biogeography, population genetics is
more used in ecological biogeography. The emergence of population genetics represents an
expressive advance in evolutionary biology, being the core of the modern synthesis (Beatty
1986) and presenting mathematical-scientific rigour for the area (Provine 1988). Dobzhansky’s
Genetics and the Origin of Species (1937) disturbed the population genetics by contradicting
the premise that populations are genetically homogeneous, which was assumed by most
geneticists at the time; Dobzhansky demonstrated that populations present not only a wide
diversity but also notable distinctions between subpopulations. The analysis of those different
gene pools in order to describe the relations between alleles/haplotypes across the geographical
distribution led to the development of a whole new area, capable to deal with both historical
and ecological biogeography: phylogeography (Avise et al. 1987; Avise 2000).
Phylogeography is an important field of evolutionary biology because it is able to
connect historical and ecological biogeography as well as phylogenetics and population
genetics (Avise 2004). Thanks to that ability, phylogeography has influenced the development
of biogeographical methods, especially those related to the reconstruction of ancestral
distribution ranges (e.g. Ree & Smith 2008; Yu et al. 2010; Landis et al. 2013). It has also
allowed a reassessment of the vicariance-dispersal dichotomy that has been kept for decades
(Zink et al. 2000). A convenient example is oceanic dispersal: widely neglected after the
discovery of plate tectonics, it was re-established through molecular dating and modern
biogeographical tools (reviewed by Queiroz 2005).
The palaeotropical region, other than being a scenario for Wallace’s first published
biogeographical works, presents a rich and troubled geological history. Researches across this
region are consequently not rare – particularly those involving the Indo-Australian Archipelago
(IAA) – and they still often succeed in offering novel contributions to evolutionary biology.
The region was a representative part in recent studies that re-evaluated oceanic dispersal’s role
in the organismal distribution (Zink et al. 2000; de Queiroz 2005).
1.4 Thesis justification and aims
One of the main reasons for which these taxa are interesting for biogeography and
evolutionary biology are the boundaries imposed to their dispersal by both terrestrial and
oceanic environments. The interest for freshwater species began early in biogeography:
Wallace (1881), Darwin (1859) and Huxley (1880) have commented or discussed the
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distribution of the freshwater species in their publications (particularly, ‘Darwin’s Bulldog’
exhibits great interest in a large-scale biogeography of the decapods (Huxley 1880)). John
Avise, underlines the relevance of such organisms in his works: freshwater organisms are
offered too many types of obstacles and, therefore, they develop the largest amount of
intraspecific genetic diversity and present strong evidence for refugia (Avise et al. 1987; Avise
2000, 2004, 2009). Unaware of plate tectonics, Darwin (1859) noticed that freshwater
organisms are good models for researching and/or testing vicariant events; besides, he
discusses the dispersal possibilities that some species could have developed.
The type species of the genus Caridina, Caridina typus H. Milne-Edwards, 1837, has
already caught scientists’ attention with its wide distribution: contrary to most Caridina
species, which are restricted to islands or specific landlocked locations, C. typus’ range is
almost completely congruent with the distribution of the entire genus (Bouvier 1925; Johnson
1960, 1961). One of the reasons for that is perhaps C. typus’ intimate connection to the coast,
with planktonic larvae and probably estuarine reproduction (Johnson 1963; Suzuki et al. 1993).
In spite of these intriguing features, this species has never gone through any populational or
phylogeographic studies, though there are suggestions that it is actually a species complex (de
Grave 2013).
This study has a two-fold aim: first, I shall use mitochondrial and nuclear loci to infer
the evolutionary history of the widely distributed populations of Caridina typus while
evaluating their taxonomic status. With the relationship between populations clarified, it will
be possible to make inferences about their ancestral distribution and how they have achieved
their current one. In order to assess C. typus’ taxonomic status under a molecular biology
approach, I shall include specimens of Caridina villadolidi Blanco, 1939 in the analyses. This
species has been previously described as a subspecies of C. typus and there’s still some
difficulty to morphologically distinguish it from C. typus (Cai & Ng 2001; Thomas von
Rintelen pers. comm.).
Such phylogeographic studies, focused on a single species, have been said to be
‘narrative’ and ‘non-empirical’ in contrast to cladistic biogeography, mainly concerned with
describing the history of the areas instead of the taxa (Humphries & Parenti 2001; reviewed by
Knapp 2005). However, as Knapp (2005) has put, patterns inferred by such works are valuable
even to cladistic biogeography itself: when multiple taxa show congruent patterns, they lead to
deeper more enlightening research – and one might add that, if they are too incongruent, they
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may also inspire new investigations. A species as C. typus, with such large distribution, across
different climates and environments, is thus priceless to biogeography. Besides, even though
C. typus is not a threatened species, it is present in 14 of the 34 current recognised biodiversity
hotspots (De Grave 2013; Fransen 2015). Therefore, apart from offering an opportunity of
addressing problems related to biodiversity (such species delimitation and understanding of the
radiation processes), C. typus may also be a candidate for bioindication of both lotic and lentic
– and, perhaps, even estuarine – environments.
Secondly, I shall make a brief review on the biogeography of the Indian Ocean
concerning terrestrial and freshwater taxa. Initially, the geological history of the cited ocean
will be appraised, drawing attention to processes and events that may influence the distribution
of non-maritime species. The taxon-range choice was made because patters and processes
involved with the distribution of oceanic species are very different from those regarding
terrestrial and freshwater species and are thus difficult to analyse at the same time (see Costello
et al. 2017). Then, I will make a meta-analysis across published phylogeographic studies on
the taxa of the continents and island bathed by the Indian Ocean: molecular biology works will
be remade (corrected and/or complemented where necessary) and submitted to ancestral range
inference.
To assist the comprehension of the results and discussions reported here, this
dissertation was arranged to have the review and meta-analysis presented before the
phylogeographic work on C. typus.
On the meta-analysis, the following question was raised:
1. Are there repetitive large-scale patterns among the distribution of different non-maritime
species?
Can the distribution of different terrestrial/freshwater taxa comprise the same or similar
processes? Can predictions be made on how the species are distributed across the Indian
Ocean? Do distinct events carry the same importance for different taxa?
Based on this question, the following aims and objectives were defined:
1. Aim:
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This meta-analysis’ aim is to re-analyse published data from animal and plant taxa from
across the Indian Ocean and establish a time-calibrated tree and the ancestral distributions in it
in order to overlay the histories of both taxa and ocean and assess events and processes that
may be involved with the biogeography of terrestrial and freshwater species.
2. Objectives:
a. To obtain time-calibrated trees as precise as possible given the data and information
in the literature for each taxon;
b. To estimate the ancestral distributions based on those trees and on the current
distribution of the analysed taxa;
c. To evaluate which biogeographical hypotheses fit the dates and ancestral ranges
contained in the obtained trees.
On the C. typus work, several questions were raised:
1. Is there geographic structure in that species?
Is there differentiation between C. typus’ populations? If so, does it reflect their geographic
distribution?
2. How and when did C. typus reach its current distribution?
Which types of processes and events are involved with this species’ distribution? What is the
relative importance of vicariance and dispersal for it?
3. What is the taxonomic status of C. typus?
Does Caridina typus comprise a single species without significant differences between
populations or is it in fact a complex of two or more cryptical species?
Based on these questions, the following aims and objectives were defined:
1. Aim:
This research’s aim is to use both mitochondrial and nuclear data to describe the
distribution of the genetic diversity of the Caridina typus’ populations, reveal whatever patterns
of geographic structure, and assess its taxonomic status through molecular systematics
methods.
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2. Objectives:
a. To test the hypothesis that different populations represent different lineages
according to their geographic arrange;
b. To evaluate the genetic diversity of different regions to assess population structure;
c. To evaluate the evolutionary history inside and between populations, to test the
hypothesis of ancient radiation and deep coalescence and to assess the existence of
multiple species inside a complex.
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Chapter 2: A brief review and analysis of the Indian Ocean biogeography –
A highway for continental species
Authors: Samuel C. Bernardes1, Almir R. Pepato1, Fabrício Lapolli2, Thomas von Rintelen3,
Kristina von Rintelen3, Timothy J. Page4,5, Björn Stelbrink6, Mark de Bruyn7,8
1Laboratório de Acarologia, Instituto de Ciências Biológicas, Universidade Federal de Minas
Gerais, Av. Antônio Carlos 6627, Belo Horizonte 31270-901, Brazil. 2Laboratório de Dinâmica
Oceânica, Instituto Oceanográfico da Universidade de São Paulo, Praça do Oceanográfico 191,
São Paulo 05508-120, Brazil. 3Museum für Naturkunde, Leibniz Institute for Evolution and
Biodiversity Science, Invalidenstraße 43, Berlin 10115, Germany. 4Australian Rivers Institute,
Griffith University, Nathan, Queensland 4111, Australia. 5Water Planning Ecology,
Queensland Dept. of Science, Information Technology and Innovation, Dutton Park,
Queensland 4102, Australia. 6Department of Animal Ecology & Systematics, Justus Liebig
University, Heinrich-Buff-Ring 26-32 IFZ, Giessen D-35392, Germany. 7Macleay Building
(A12), Faculty of Science, University of Sydney, Science Road, Sydney NSW 2006, Australia.
8School of Biological, Earth and Environmental Sciences, University of New South Wales,
Sydney NSW 2052, Australia.
2.1 Abstract
The Indian Ocean has been a recurrent target to biogeography due to its unique geology and
controversial biological feature: such as areas of high endemism, complex history and mixed
elements. Much discussion has been placed on the topic and each of Indian Ocean’s landmasses
may represent a particular field of study. Here we re-analyse published data on Indian Ocean
taxa by constructing time-calibrated phylogenies and inferring ancestral distribution ranges.
Our results suggest that India has a mixed history and that it is naïve to expect signs of
continued isolation since its break-up from Gondwana. Also, they show that the islands at the
African eastern coast are intimately related and that Eastern and Western Indian Ocean have a
spliced evolutionary history. Furthermore, we discuss the obstacles of inferring the
biogeographic history of the region.
2.2 Introduction
The Indian Ocean is the smallest, youngest and warmest of the three major oceans
(Atlantic, Indian and Pacific). It bathes areas of great geologic and biogeographic interest,
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11
including the African, Asian and Australian continents, the Indian subcontinent, the Indo-
Australian Archipelago (IAA), the Arabic Peninsula, and important islands such as
Madagascar, Seychelles, Comoros and the Mascarene Islands. Even though the Australian
western oceanic crust has shown to be 140 million years (Ma) old – which suggests that the
ocean’s initial opening may share that age (Heirtzler et al. 1973) –, the Indian Ocean’s origin
is much more complex and recent, as it involves successive seas and oceans’ openings and
closures (see below).
The Indian Ocean’s climate is affected by a monsoon system, especially in the Northern
Hemisphere. The winds blow towards the southwest from October to April and in the opposite
direction from May to October. That pattern leads to two very well delineated seasons –
respectively, one cold and dry and another warm and rainy. The Southern Hemisphere is less
influenced by the monsoon, with milder winds; nonetheless, it suffers with severe storms
during summer due to the northeast winds (Clemens et al. 1991; Gadgil & Srinivasan 2011).
In fact, the Indian Ocean’s monsoon is so marked that it can cause extensive changes in the
oceanic currents of the north hemisphere: during the winter monsoon, two smaller gyres are
formed at east and west of the Indian subcontinent (Tomczak & Godfrey 1994; Schott et al.
2002).
In addition to being the hottest ocean in the planet, the Indian Ocean also suffers with
the highest levels of annual warming, especially in its western section. Such warming is
intimately linked to global warming and to El Niño, and they show how El Niño can induce an
abnormal warming on other oceans, which La Niña isn’t able to revert completely (Roxy et al.
2014). The abnormal oceanic warming could also be associated to the weakening of the rainfall
regimen during the summer monsoon since precipitation weakening in the Indian Ocean is
correlated to rises in the sea surface temperature (Roxy et al. 2015). With those peculiar
warming properties, there is a blatant concern for the region in what touches global warming
(Roxy et al. 2014; Latif et al. 2017; Aneesh & Sijikumar 2018).
Such outstanding recent findings underline how dynamic the geography of the Indian
Ocean can be. It is not surprising that this ocean has become a prolific field for biogeography
and a laboratory for studies on continental drift (see Hocutt 1987; Chatterjee et al. 2013).
However, the region remains fertile to discoveries both about Earth’s crust dynamics (e.g.
Bybee et al. 2010; Ashwal et al. 2017) and about the distribution of the organisms across the
world (e.g. Pyron 2014; Jurado-Rivera et al. 2017).
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12
2.3 Overview of the Indian Ocean’s geology
The history of the Indian Ocean begins with Tethys, an ancient sea located in the eastern
Pangaea. It lasted from the Devonian to the Cenozoic, but, it’s now understood that Tethys had
neither temporal nor spatial stability; in fact, it comprised several oceans that were opened and
destroyed, leading to the current nomenclature: Paleo-Tethys (a sea that lasted from the
Devonian to the Triassic), Meso-Tethys (from the Permian to the Cretaceous) and Ceno-Tethys
(from the Triassic to the Cenozoic). The duration of these seas overlapped because the
expansion of each of these oceans would eventually cause the collapse of the earlier ocean
(Metcalfe 2013). There is no semantic consensus on the origin date of the ‘Indian Ocean’ as
we understand it. Some authors namely call ‘Indian Ocean’ the sea created at south of the
Indian subcontinent by its movement northwards (e.g. Metcalfe 2013). Other authors only use
the term Indian Ocean to refer to the ocean left after the collision between India and Eurasia at
the transition Oligocene-Miocene, i.e., the ocean left after the complete destruction of Tethys
(e.g. Hall 2012).
During the Late Jurassic, 160 Ma ago, Pangaea was breaking into two new continents,
Laurasia and Gondwana. At this time, Gondwana was also initiating a fragmentation process
that began by the separation of Australia and India. The Australia-India breakup forced the
Ceno-Tethys northwards and started the collapse of the Meso-Tethys (Fig. 2.1a) (Chatterjee et
al. 2013). The separation between India and Australia, 140 Ma ago, marked the beginning of
the Cretaceous period (Fig. 2.1b) and, as India moved to the north, it carried Madagascar with
it (Fig. 2.1c). The separation between these two landmasses only happened 90 Ma ago (Fig.
2.1d) (Raval & Veeraswamy 2003; Hall 2012; Metcalfe 2013) followed by the separation of
the Seychelles sometime near the end of the Cretaceous (Collier et al. 2008). Meanwhile,
Australia drifted eastwards; the rift between Australia and Antarctica was initiated by the
Gondwana break-up but both continents were still widely connected until a second rift event
in the Late Cretaceous. With the second rift event, Australia initiated the movement northwards
(Hall & Keetley 2009). In the Palaeocene, when the IAA did not exist yet, the Sunda shelf was
presented as a peninsula in south-eastern Asia (Fig. 2.1e). The IAA was originated from the
movement of the Australian plate towards the shelf: throughout the Cenozoic, such motion
generated thousands of volcanic islands, rotated Borneo anticlockwise and eventually set the
current boundaries of the Pacific Ocean. The northernmost portion of the Australian plate, a
promontory named Sula Spur, collided with the southernmost portion of the Sunda shelf in the
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13
Miocene. The encounter caused the collision of several islands that gave rise to Sulawesi.
Sulawesi’s formation established the contact between the Australian and Eurasian plates and
ended the wide connection between the Pacific and Indian oceans (Hall 2011, 2012).
During the Cenozoic, the Indian Ocean’s currents were unstable due to India’s
movement (Barron & Peterson 1991). However, after its collision with Asia, the shallow
circulation became simpler, basically resumed to an equatorial flow off the Pacific towards
Africa and a flow back to the Pacific from the southwest (Barron & Peterson 1991; Thomas et
al. 2003). At 14 Ma, the strait between Sula Spur and the Sunda shelf became so narrow that
the equatorial flow back to the Pacific was interrupted and a strong westward equatorial current
took place in the Indian Ocean (Fig. 2.1f) (Gourlan et al. 2008). The current, called Miocene
Indian Ocean Equatorial Jet (MIOJet), lasted for over 10 Ma and not only increased the
transportation westwards but also diminished the transportation eastwards. The establishment
of the MIOJet altered that dynamics in such a way that the surface circulation became almost
restricted to the jet (Barron & Peterson 1991; Gourlan et al. 2008).
The complexity of the Indian Ocean’s evolution drew attention of geologists for
decades and now it is very well understood. Such complexity is mostly due to the India’s
movement: as the subcontinent passed to the north, it influenced not only the oceanic
circulation but also climate and the shape of the continents as multiple volcanic hotspots
became active. The most significant hotspots in the Indian Ocean are the Kerguelen hotspot
and the Réunion hotspot. The Kerguelen hotspot began to erupt in the Early Cretaceous and is
therefore related to the Antarctica-Australia-India break-up (Coffin et al. 2002). The Réunion
hotspot (and the Deccan Traps) became active in the K-Pg boundary and may be related to the
India-Seychelles separation. Each of these hotspots produced a long ridge across the Indian
Ocean – east and west of India respectively (Fig. 2.1f) – with subaerial elements in the
Cretaceous and Cenozoic (reviewed by Chatterjee et al. 2013). The Deccan Traps are
particularly interesting as, for decades, their eruption has been suggested to be an explanation
the mass extinction occurred at the end of the Cretaceous period (e.g. McLean 1978;
Venkatesan et al. 1993; Keller et al. 2011), competing with the popular bolide impact
hypothesis, which itself presents compelling evidence (Schulte et al. 2010). Some authors,
however, don’t see the two hypotheses as alternatives (Schoene et al. 2014; see Keller 2014)
and some studies have suggested causal connectivity between the two, where the impact would
have set off the tectonic instability (Renne et al. 2015).
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Figure 2.1: Geologic reconstruction of the Indian Ocean’s continents through the Mesozoic and Cenozoic at
155 Ma (a), 140 Ma (b), 110 (c), 90 Ma (d), 65 Ma (e) and 14 Ma (f). Laurasian landmasses are represented in
red and Gondwanan landmasses are represented in green. Areas in yellow are volcanic islands and in cyan are
volcanic ridges (90E: Ninetyeast Ridge; CL: Chagos-Laccadive Ridge) and plateaus. The oceans are in blue.
The lightly coloured areas next to the continents represent the respective continental shelves, which may or may
not be emerged depending on the time. Dashed lines represent boundaries of continental break-ups; green
arrows represent major break-up events; and the blue arrow represents the MIOJet. KP: Kerguelen Plateau; MI:
Mascarene Islands; SS: Sula Spur. Modified from Hall 2012 after Chatterjee and Scotese 2010 and Chatterjee
et al. 2013.
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15
2.3.1 On the Eastern Indian Ocean
The most obvious outcome of the collision between the Indian subcontinent and the
Eurasia 50 Ma ago was the formation of the Himalaya. The uplift of the Himalaya had an
extensive influence over the climate, not only Asian but worldwide: it is now seen as a major
contributor to the establishment of the monsoon system and it favoured the glaciation of the
Northern Hemisphere (reviewed by Chatterjee et al. 2013). Nevertheless, the encounter also
helped to push the Sunda shelf eastwards, and thus contributed to the formation of the IAA and
to the rotation of the Greater Sundas – Borneo, Sumatra and Java (Allen et al. 2008). By the
time of that collision, Australia, still connected to Antarctica, was accelerating its northwards
movement, triggering the process of emergence of the IAA as described above (Hall 2002).
The IAA formation defined the eastern boundary of the Indian Ocean and changed its dynamics
completely.
As said in the previous section, though, the IAA did not exist in the Early Cenozoic and
the Sunda shelf was a promontory at the south-eastern portion of Eurasia. During the
Palaeocene, when the climate was similar to nowadays (perhaps warmer and wetter), the Sunda
shelf probably exhibited environmental complexity, with mountains, rivers and equatorial
forests. However, the climate changed in the Middle Miocene, leaving the area drier and more
seasonal (Morley 2000). The emerged area decreased consistently until the Late Miocene,
when the contact between Sula Spur and the Sunda shelf initiated in the Early Miocene
expanded and the Makassar strait (a rift currently between Borneo and Sulawesi) was formed
(Hall 1996, 2002). The encounter between Sula Spur and Sunda also caused the uprising of
mountains and landmasses such as Borneo (Hall 2002) (see fig. 2.1e). The uprising of
mountains, the expansion of shallow seas and the changes in the circulation caused by the
MIOJet contributed to the establishment of a wetter climate, which made the forests expand
again in the region (Morley 2000). The collision also augmented the emerged area of the
Wallacea, the middlemost region of the IAA, including Sulawesi, Halmahera, Taliabu and the
Lesser Sundas (Timor, Flores, Sumba etc.) (Hall 2002).
2.3.2 On the Western Indian Ocean
The breakup between India and Madagascar in the Cretaceous initiated the formation
of the Western Indian Ocean’s islands. The fragmentation is important to geology in multiple
levels; more recently, new evidence culminated in the discovery of a previously unknown
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16
microcontinent called Mauritia. These findings reveal that the India-Madagascar separation
also involved the fragmentation of the cited microcontinent (Torsvik et al. 2013; Ashwal et al.
2017). Soon after the separation of Madagascar, at some point in the Late Cretaceous, the
Indian subcontinent broke from the Mascarene Plateau, where the Seychelles are located. The
Mascarene Plateau is a submarine plateau of mixed origin: whereas the northern part (with the
Seychelles) is granitic, the southern part, which includes the Mascarene Islands is volcanic
(Ashalatha et al. 1991). The granitic portion is actually a 750 Ma old microcontinent whose
fragmentation began in the Carboniferous and may have triggered the India-Madagascar-
Seychelles separation (Plummer & Belle 1995; Torsvik et al. 2001). The Seychelles are
therefore the oldest known granitic islands, which implies that their geological stability is
considerable.
As said above, the Réunion hotspot became active in the K-Pg boundary and was
responsible for the formation of the southern part of the Mascarene Plateau. The hotspot kept
active for millions of years and generated many islands as well as the Chagos-Laccadive ridge,
south-eastern to India (Fig. 2.1f). The Laccadive Islands, the Maldives and the Chagos
Archipelago were the first islands to emerge between 60 and 45 Ma ago. The Mascarene Islands
would only begin their slow emersion at 35 Ma: first, the Saya de Malha bank emerged
followed by the Nazareth Bank, both submarine nowadays; Mauritius would emerge next,
approximately 10 Ma ago; Réunion and Rodrigues were the last ones at 2 Ma (Ashalatha et al.
1991; Verzhbitsky 2003). As for Madagascar, after its breakup from India, the island moved
away from Africa very slowly. In part, it was due to the Réunion hotspot’s activity and to the
expansion of the Chagos-Laccadive ridge across the Mascarene Plateau (Verzhbitsky 2003; Ali
& Aitchison 2008). Even though it is probably not related to this movement, the origin for the
Comoros hotspot (between Africa and Madagascar) is still a controversial topic. The Comoros
Islands (including Mayotte) are an outcome of this hotspot; the region still presents a strong
volcanic activity and the islands are somewhat isolated from both Africa and Madagascar
(Esson et al. 1970; see Barber-James 2008).
2.4 The Indian Ocean’s biogeography
‘Probably no theory has shaken the foundations of biogeography more than
Croizat’s (1958) panbiogeography which broke from traditional dispersal models (…)
in favour of vicariance theory.’
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Charles H. Hocutt (1987), Evolution of the Indian Ocean and
the drift of India: A vicariant event
In the previous sections, it has been made clear how complex the history of the Indian
Ocean is. Such complexity can be translated in richness when it comes to biodiversity. The
Indian Ocean is intimately related to the history of five continents (Africa, Antarctica,
Australia, India and Eurasia); therefore, after the emergence of the vicariant biogeography, it
became a laboratory for studies in historical biogeography (see Hocutt 1987). Such studies
suggest not only major vicariant hypotheses involving plate tectonics but also draw attention
to one of the new directions given to historical biogeography by the vicariant theory: ‘areas of
endemism’ (Nelson & Platnick 1981). The concept and the criteria to define areas of endemism
has been largely debated: Henderson (1991) criticise the very study of the relationship of areas
in biogeography and pointed that the criteria to identify areas of endemism are poorly defined.
Linder (2001), however, argues that methodological refinement can make the delimitation of
areas of endemism objective. Following the notion that the concept of areas of endemism
involves only space and not time, Noguera-urbano (2016) proposes that studies on endemism
would be enriched by the evaluation of the relations between endemic species through time,
i.e., through phylogenetic information. In spite of such heated debate, it is noteworthy that
some of the most iconic areas of endemism are bathed by the Indian Ocean: Australia,
Madagascar, the Mascarene islands, the Seychelles, just to cite a few.
India itself has been seen as a good model for studies in historic biogeography for the
time it spent travelling in isolation across multiple climatic zones. India’s biogeographic
isolation has been questioned for decades: Briggs (1989) points out that, even though the
geophysical evidences indicate 100 Ma of an isolated subcontinent, the palaeontological data
does not exhibit the expected endemism for such scenario. However, Patterson and Owen
(1991) show that some of Briggs’ arguments fail to support his claims of a non-isolated India.
Over two decades later, Verma et al. (2016) reviewed the prolific palaeontological discoveries
since the 1980’s in the region and showed that some of the endemism expected for the Late
Cretaceous period was in fact there, but mixed elements (Gondwanan and Laurasian) indeed
predominate in the fossil assemblages. An intriguing fact of such debate is that the current taxa
represent the isolation indicated by the geological history better than (sometimes even in
disagreement with) the fossil assemblages, with some studies providing evidence for an ‘Out-
of-India’ hypothesis for the presence of Gondwanan forms in Asia (e.g. Conti et al. 2002;
Gower et al. 2002; Biju & Bossuyt 2003; Datta-Roy & Karanth 2009; Whatley 2012). Many
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bridges have been hypothesised to explain the presence of taxa of foreign affinities in India.
Chatterjee and Scotese (2010; also see Chatterjee et al. 2013) present compelling evidence for
two of those bridges: the Oman-Kohistan-Dras Arc would serve as a connection to Africa in
the Late Cretaceous (and to Asia in the Cenozoic) (see fig. 2.1d,e); at the same time, the
Ninetyeast Ridge plus the Kerguelen Plateau would connect Indian and South American faunas
via Antarctica (see fig. 2.1e,f). Other proposed bridges would have linked Africa and India via
Madagascar through currently submerged elements of the Mascarene Plateau and the Chagos-
Laccadive ridge (e.g. Sahni 1984) or through the Seychelles (Rage 1996, 2003; Ali & Aitchison
2008).
Until the end of the Cretaceous, India carried Madagascar and the Seychelles in its
journey northwards. Madagascar has one of the highest levels of endemism in the world,
including 100% of the mammals and amphibians, 92% of the reptiles and over 90% of the
plants (reviewed by Vences et al. 2009). In addition to this outstanding endemicity, Madagascar
has a very heterogenous landscape, similar to larger continents, with several different climatic
and vegetation zones (de Wit 2003), a scenario that drew the attention of Alfred Russel Wallace
(1881) himself: ‘Madagascar possesses an exceedingly rich and beautiful fauna and flora,
rivalling in some groups most tropical countries of equal extent, and even when poor in species,
of surpassing interest from the singularity, the isolation, or the beauty of its forms of life.’ Its
fauna has always been very Gondwanan, including derived Abelisaurid dinosaurs similar to
those found in South America in the Late Cretaceous (Sampson et al. 1998), but Laurasian
forms invaded the island very soon in the Tertiary, including reptiles, mammals and plants
(Rage 1996; Schatz 1996; see Krause 2010). It is geologically understood that Madagascar
became isolated as soon as it was detached from India (Reeves & de Wit 2000; see Fig. 2.1d)
and such scenario, as it is for India, presents opportunities for the proposition of new land
bridges. One of the most debated (and no longer accepted) bridges for Madagascar is the so-
called ‘Lemuria’ proposed by van Steenis (1962) for the Cretaceous. Schatz (1996) proposed
that, though Lemuria is not supported by any geological evidence, the Eocenic India and
elements of the Mascarene Plateau could have served as “Lemurian Stepping-stones” for
Laurasian organisms. Since then, several studies have evoked these stepping-stones as an
explanation for faunal/floral exchanges between Laurasia and the Gondwanan elements of the
Indian Ocean (e.g. Wikström et al. 2004; Klaus et al. 2006; Trénel et al. 2007; Moyle et al.
2012).
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Only in 2010, Warren et al. have provided strong evidence for the existence of such
stepping-stones across the Seychelles and Mascarenes. These archipelagos, though smaller in
size and poorer in ecological complexity when compared to Madagascar, exhibit remarkable
levels of endemism: for example, in both archipelagos over 50% of the native resident species
are endemic (Adler 1994). Separated from India in the Late Cretaceous, the Seychelles are
much older than the Mascarenes (see previous section); yet there are examples of taxa that can
be found in both archipelagos, but are not found neither in Madagascar nor in Africa which is
in agreement with the stepping-stone hypothesis (Warren et al. 2010). Also in agreement with
an island presentation that favours the Lemurian Stepping-stones is the historic distribution of
tortoises (Braithwaite 2016; Cheke et al. 2016; Hansen et al. 2016; Hawlitschek et al. 2016)
and other reptiles (reviewed by Hawlitschek et al. 2016) in the Indian Ocean. Nevertheless,
Thornton et al. (2002) questions the relevance of stepping-stones in the colonisation of islands.
As he discusses, since good dispersers will be able to reach a location without the aid of a
stepping-stone whereas poor dispersers may fail to do so even in the presence of a stepping-
stone, the distance covered by the stepping-stone should be near the dispersal limit of a said
species. Moreover, environmental divergences between the target island and the stepping-stone
may play an important role in defining the spectrum of species that are able to use such
dispersal path. To date an island’s endemism is also a difficulty to study and hypothesise on
the historic dispersal across islands: Pillon and Buerki (2017) showed that extinction has been
an overlooked phenomenon in biogeography and insular lineages may have diverged previous
to the emergence of the island itself.
On what comes to marine organisms, things may seem a little simpler, but they also
failed to fulfil historic biogeography’s predictions; Heads (2005), reviewing the prominence of
panbiogeographic patterns in marine biota, pointed to many works that demonstrate a vicariant
origin of the marine species from Tethyan ancestors. In fact, some interesting cases show a
clear endemism boundary between eastern and western Indian Ocean: for instance, both extant
species of coelacanths are found in the Indian Ocean, one in Comoros and the other in the IAA
(Holder et al. 1999; Springer 1999). Other examples of such east-west provinces are not rare
and can be observed in the blenniid genus Ecsenius McCulloch, 1923 (Springer 1988), in
pigeons – where several genera found in the Malagasy islands exhibit transoceanic
relationships, including Alectroenas-Drepanoptila, Raphus/Pezophaps-Caloenas and multiple
species in the genus Treron Vieillot, 1816 (Shapiro et al. 2002; Pereira et al. 2007; Gibb &
Penny 2010) –, and in lizards (e.g. Rocha et al. 2006; Heinicke et al. 2014) to cite a few. Some
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of these, however, may not represent Croizat’s school so well as some may believe:
developments in dating speciation events in a phylogeny using molecular data made possible
to discard tectonics as responsible for some disjunct distribution across the taxa (reviewed by
de Queiroz 2005). For example, there are some single species cases of this eastern-western
division in the Indian Ocean – e.g. the gastropod Cerithium gloriosum Houbrick, 1992, found
in the Comoros and in Borneo (Houbrick 1992), and the freshwater shrimp Caridina typus H.
Milne-Edwards, 1837, a species complex found across all of the Indian Ocean (Bernardes et
al. 2017 and Chapter 3 below) – and imply that gene flow is still happening or has happened in
recent times.
The Indian Ocean bathes areas intensively targeted by the panbiogeography school, but
still holds many puzzles unanswered. Linder (2001) criticises the approach by some
panbiogeographers to demonstrate vicariance by evaluating incongruence in the composite
areas: ‘(…) this means that incongruence could be caused by either poor area delimitation or
dispersal, with no mechanism for deciding between these two hypotheses. The possibility of
refuting process explanations of vicariance is thus weakened’ (p. 893). The methodological
development in the last two decades should have eliminated such arguments from authority
used to criticise new findings that are incongruent with the previous literature, but the debate
stands and much of Indian Ocean’s biogeographical history remains unsolved. Here we shall
review the molecular phylogenetic and phylogeographic works made in the Indian Ocean and
apply the latest methods to them in order to assess their biogeographic information. This will
be then used to propose a history to the Indian Ocean continents and islands.
2.5 Materials and methods
2.5.1 Studies chosen
Search for studies to be used in this meta-analysis was conducted in Google Scholar
and Web of Science. Our choices were based on three criteria: (1) they should be centred in
either terrestrial or freshwater taxa; (2) they should be based on molecular data, namely DNA
sequences; and (3) they should be focused on phylogenetic reconstructions. With such criteria,
we used seven published researched about the landmasses in the Indian Ocean (Table 2.1). We
chose papers that included more than one of the defined landmasses: continental Africa,
continental Asia, Australia, Comoros, India, Indo-Australian Archipelago, Madagascar,
Mascarene Islands and Seychelles.
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2.5.2 Phylogenetic analyses
All phylogenetic analyses were conducted in BEAST 2 v. 2.4.0 (Bouckaert et al. 2014)
and aimed to replicate the results obtained by the original authors in order to test them – if they
could not be replicated they were either mistaken or not clear about the used methodology.
However, we observed three issues with repeating the exact same procedure described by the
authors. First, some of the works do not give enough detail to allow a precise replication of
Table 2.1: Works analysed in this dissertation
Taxon Taxonomic
level
Distribution Reference Calibration Markers
Pteropodidae Family Af, As, Au,
C, In, IAA,
M, MI, S
Almeida et al. 2011,
2014
Hassianycteris
kumari Smith et al.
2007;
12S, 16S, CytB
Dates from
Agnarsson et al.
(2011)
BRCA1, RAG1,
RAG2, vWF
Chamaeleonidae Family Af, As, C,
In, S
Raxworthy et al.
2002
Same as in Tolley et
al. (2013)
16S, ND2, ND4
Tolley et al. 2013 PRLR, RAG1,
CMOS, AKAP9,
BACH1, BACH2,
BDNF, MSH6,
NKTR, REV3L
Cryptoblepharus Genus Af, Au, C,
M, MI
Rocha et al. 2006 Rates for 12S and
16S after Skinner et
al. (2007)
12S, 16S
Ebenavia
inunguis
Species Af, C, M,
MI
Hawlitschek et al.
2017
Rates for 12S, CytB
and RAG2 after
Carranza & Arnold
(2012)
12S, CytB, COI
RAG2, PRLR
Boidae Family Af, As, Au,
M, I
Noonan &
Chippindale 2006
Same as in Noonan
& Chippindale
(2006)
CytB
RAG1, BDNF,
CMOS, NT-3,
ODC
Anatini Tribe Af, As, Au,
I, IAA, M
Mitchell et al. 2014 Same as in Mitchell
et al. (2014)
12S, CytB, COI,
ND2
Neobatrachia Suborder Af, As, Au,
I, IAA, M, S
Frazão et al. 2015 Same as Feng et al.
2017
12S, 16S, ND1,
CytB
Feng et al. 2017 C-MYC2, C-
MYC3, H3A,
POMC, RHOD,
RAG1, SIA,
TYRPREC
Area abbreviations: Af - Africa, As - Asia, Au - Australia, C - Comoros, I - India, M - Madagascar, MI -
Mascarene Is., S – Seychelles
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their work. Second, many works fail to apply the best tools or the appropriate empirical priors
to their Bayesian analyses. Third, to facilitate the obtention of convergence was a main concern
for us due to the large number of Bayesian analyses to be performed. With these issues in mind,
we established a routine to set each analysis:
(I) Data handling: we would use every information made available by the authors in our
first approach to the data (alignment, partitioning, priors etc.). Nonetheless, some of the works
did not use the best approach to treat the data before the analysis: for example, many papers
used ribosomal markers without applying a secondary structure to their alignment (without
using a secondary structure as a base for the alignment of such markers, the proposed primary
homology will inevitably present errors);
(II) Substitution model: jModelTest 2.1 (Darriba et al. 2012) was used to calculate the
best named model (e.g. JC, HKY, GTR) for each marker or partition indicated by the authors,
but all analyses were performed using a reversible-jump method to choose the best substitution
model (Huelsenbeck et al. 2004; Bouckaert et al.2013). The reversible-jump method was
chosen instead of a named model because (1) it facilitates convergence since it is able to find
the least parametrised model to fit the data (see Grummer et al. 2014) and (2) it makes the
phylogenetic estimation independent of a specific model by integrating it over the parameters’
uncertainty (Huelsenbeck et al. 2004). However, our previous experience shows that a better
convergence is obtained when offset values for the model parameters (such as invariant
proportion) are empirically obtained through jModelTest;
(III) Molecular clock: all molecular clocks were initially set to relaxed with a lognormal
distribution. The strict clock is a special case of the relaxed clock where there is no variation
of the rates along the branches. After the preliminary analyses, those markers that presented
the distribution of the clock’s standard deviation centred in zero were set to a strict clock. The
remaining relaxed clocks would then be tested for an exponential distribution. If there were
differences in convergence or topology, the two distributions, lognormal and exponential,
would be tested against each other through an AICM approach (Raftery et al. 2007; but see
Baele et al. 2012);
(IV) Tree priors: all trees were initially set to either a Yule or a Coalescent model and
lognormal distribution for all priors. A Yule model would be set for multispecies analyses and
Coalescent models would be set for analyses involving a single species. Yule and Birth and
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Death models were alternatives according to the convergence. The distribution and parameter
values of the priors were set according to assessments made through TRACER v1.6
(Drummond et al. 2012);
(V) Calibration: as one of the main concerns of this study is to describe the history of
the taxa distribution, we were very attentive to calibrations. Since some of the works were not
preoccupied with dating their phylogeny, we sought in the respective taxon literature for
available calibration tools. Calibration methods of three types were found across the works we
found – fossil, molecular rate and secondary calibrations obtained from larger phylogenetic
studies –, and, therefore, we saw no reason to avoid any of these methods. Geological
calibrations such as island emergence were not used since we agree with the points raised by
Pillon and Buerki about the relationship between a taxon age and an island age (2017). We
used the calibration points and substitution rates of the source paper (when available) and/or
from secondary sources (see Table 2.1). All of our analyses were calibrated.
Alignments were done separately and, due to the variety of markers, several methods
and softwares were used. All analyses were run for 500 million generations sampling every 50
000 generations. They were visually assessed in TRACER and submitted to either 20% or 25%
burn-in, depending on the convergence obtained. Final maximum clade credibility trees were
obtained through TreeAnnotator by using the same burn-in percentage. All analyses in
BEAST2, MAFFT (Katoh & Standley 2013) and jModelTest were run in CIPRES (Miller et
al. 2010).
Table 2.2: Coordinates used for areas of
interest in BayArea
Area Latitude Longitude
Africa -1.2500 25.7225
America 10.7769 -79.1874
Asia 39.7054 81.8409
Australia -24.1385 133.3899
Comoros -12.1837 44.0731
Europe/
Mediterranean 36.637 -2.9501
IAA 1.2500 113.4847
India 20.6835 79.1195
Madagascar -19.4258 46.6878
Mascarene -20.2856 57.5659
New Zealand -43.6889 171.002713
Pacific -13.9791 -173.2304
Seychelles -4.7005 55.4899
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2.5.3 Biogeographic analyses
We inferred ancestral areas of distribution in RASP 4.0 (Yu et al. 2015) – RASP 4.0
also implements BioGeoBEARS (Matzke 2013) and thus allows to also use all features
available at this package. Localities of the specimens and distribution of species were obtained
from the original papers or from web sources (IUCN, The Reptile Database, GenBank). These
localities were designated to one or more of each areas described in table 2.1 – note that IAA
includes part of the continental Southeast Asia since they were connected by land through much
of the Cenozoic. Models were tested through BioGeoBEARS, but both DEC (Ree & Smith
2008) and BayArea (Landis et al. 2013) as implemented in both RASP and BioGeoBEARS
were run in order to find incongruences between methods. BayArea was run both with and
without coordinates (table 2.1) for the same reason. All analyses were run for 20 million
generations sampling every 4 000, with unconstrained settings for dispersal with a maximum
range size of three areas.
BayArea/DEC inferred areas were represented on the trees obtained in BEAST; inferred
ancestral distributions with probabilities under 0.5 were removed from further consideration.
Also removed from consideration were dispersal/vicariance events that did not involve the
Indian Ocean (e.g. Africa-America or America-Australia).
2.6 Results
2.6.1 Ancient taxa diversification
Figure 2.2 shows the biogeographical history of each taxon. On the left are the time-
calibrated trees with the calculated ancestral areas of distribution. Each colour on the branches
represents an area according to the legend (and to the map) and more than one colour (striped
branches) represent more than one area included in the distribution range (to avoid confusion,
the range is described at the branch). Time table is located below the phylogenies for temporal
orientation based on the mean age of each node. On the right are the maps with the respective
described events. Arrows are coloured based on the Period/Epoch in which the event occurred.
The meta-analyses of the published data identified a very complex biogeographic
history mostly based on dispersal throughout the Cenozoic. Only three events were identified
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Figure 2.2: Ancestral area reconstruction and biogeographic history. On the left are the ancestral reconstructions
as inferred by BayArea and DEC on calibrated phylogenies for Boidae (a), Neobatrachia (b), Chamaeleonidae
(c), Pteropodidae (d), Anatini (e), Cryptoblepharus (f) and Ebenavia inunguis (g). The branches colours
represent the correspondent area in the maps on the right according to the legend. The maps on the right
represent our interpretation of each taxon’s biogeographic history. Areas not represented in the map are
presented at the branches. The arrows represent biogeographic events and are coloured according to the
Period/Epoch in which they happened according to the legend below each map. One-way arrows represent
dispersal and two-way arrows represent vicariance.
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Figure 2.2: Cont.
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to take place in the Mesozoic (Fig. 2.2a,b,c) and not coincidently among those are also the only
two vicariance events that we were able to point out. Boid snakes, chameleons and frogs are
part of a non-volant less vagile herpetofauna (with some remarkable exceptions among the
Neobathachia). However, all three taxa are very old in age and should be good models to assess
vicariance events and ancient continental history. For instance, Boids were widely distributed
across Gondwana and their current distribution seems to be intimately related to its
fragmentation. Nonetheless, their colonisation of India seems to have been caused by dispersal
from Antarctica-Australia (Fig. 2.2a). Alternatively, Gondwanan frogs present an example of
an Indian clade that travelled with the subcontinent and went through a vicariance speciation
with the separation of the Seychelles (Fig. 2.2b).
Although complex histories are offered by boids and frogs, chameleons exhibit a much
simpler scenario: they remained a typically African taxon with multiple dispersals to
Madagascar. Though the first dispersal to Madagascar occurred by the end of the Cretaceous,
their diversification happened entirely through the Cenozoic.
2.6.2 Volant taxa diversification
Figure 2.2 (d) and (e) show respectively the biogeographic history of the pteropodid
bats and dabbling ducks, both volant highly vagile taxa. The pteropodid bats seem to have been
originated in the Australia-IAA and diversified from this area, including several dispersal
events between this area and Africa. At the time of such dispersal toward Africa, India was
already in contact with Eurasia and could not serve as a stepping-stone – and this is also
indicated by the IAA origin of the Indian species – but strong westwards surface currents were
Figure 2.2: Cont.
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present at the time in the Indian Ocean (Gourlan et al. 2008). Winds are intrinsically related to
surface currents and, as some pteropodid species have high migratory capabilities (Fenton
2001), they could have either flied or used rafts to travel across the ocean.
The same transoceanic dispersal occurred several times for the Anatini, but in much
more recent times (late Pliocene and Quaternary). These animals are known to be migratory
and their range cover all continents bar Antarctica, thus it is safe to assume that such dispersal
was accomplished simply by flight.
2.6.4 Recent taxa diversification
As expected, the histories of taxa in genus (Cryptoblepharus Wiegmann, 1834; Fig.
2.2f) and species (Ebenavia inunguis Boettger, 1878; Fig. 2.2g) levels involve much more
recent events. The distribution of both taxa is centred in Madagascar and both were able to
colonise Africa and the Comoros and Mascarene islands. Ebenavia inunguis was apparently
able to use the Comoros as stepping-stones to reach Africa. These two lizard taxa present
similar dispersive ability and the dispersal events inferred by ancestral area reconstruction seem
to be inside their reachable area.
2.7 Discussion
2.7.1 On an isolated India and its relationship with Seychelles and Madagascar
The Indian subcontinent (and its related islands, Madagascar and Seychelles) travelled
through a very dynamic region with the emergence and termination of several landmasses. The
idea that it was completely isolated is thus naïve. We were able to recover dispersal events to
India from Gondwana, Eurasia and Africa-Arabia throughout the Cenozoic whereas only the
Neobatrachia show a clade being originated by India’s initial break-up. India, as reviewed by
Verma et al. (2016), have its own endemism, but its fauna was composed by mixed elements
already in the Cretaceous. The fact that Indian Cretaceous fauna is shared by Madagascar,
Africa and South America suggests that the subcontinent probably remained connected with
Gondwana at the beginning of its separation. In addition, the early acquisition of Laurasian
forms in the fossil assemblage indicates that some connection should exist in the north as well.
The problem, then, lies in identifying when and how these migrations happened. Chatterjee
and Scotese (2010) gave a considerable insight into applying the geological knowledge into
this matter, but the dates of their proposed bridges are still a matter of debate. Furthermore,
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some groups in our meta-analyses still present evidence for transoceanic recent dispersal that
cannot rely upon ancient bridges (Fig. 2.2b,c,d,e). That may be the reason why recent and
contemporary taxa represent India’s endemism better than the fossil species. Nevertheless,
before drawing conclusions, we must put more effort into including Indian taxa to the meta-
analyses as these recent transoceanic dispersals are mostly from volant organisms.
Among the bats of the genus Pteropus Brisson, 1762 a recent quick diversification
shows an interesting scenario of dispersal. A group from the IAA, colonised India, then,
Seychelles and, from there, Madagascar, the Comoros and Mascarene islands (Fig. 2.2d). For
the chameleons, a much simpler situation is seen when it comes to Indian clades: they used the
Arabic peninsula as a stepping-stone to reach India (Fig. 2.2c). The ancestral area
reconstruction of Gondwanan frogs indicates that Asian clades were mostly generated by
dispersal from Asia and IAA with one notable exception (Nasikabatrachus Biju & Bossuyt,
2003) that originated the Seychellois genus Sooglossus Boulenger, 1906 by vicariance at the
K-Pg boundary (Fig. 2.2b). Boids, a relatively ancient taxon, show an early dispersal to an
already drifting India in the Paleocene, perhaps through the Kerguelen Plateau-Ninetyeast
Ridge (Chatterjee & Scotese 2010). India would then have served as a raft to allow Asian
colonisation (Fig. 2.2.a).
These scenarios show heterogeneity in the colonisation of India. As discussed in the
introduction, there is plenty of evidence for India serving as a Gondwanan ark toward Laurasia.
Conversely, there’s also plenty of evidence for early invasion by Laurasian forms (e.g. Prasad
2012; Khosla 2014). At the end of the Cretaceous, the Indian Ocean was a very troublesome
region, with intense volcanism, breaking continents and changing climate; those times may
hide scenarios that we are currently unable to recover. However, our analyses show that the
influence that dispersal has exerted on India’s colonisation should not be ignored.
2.7.2 On the colonisation of the Indian Ocean islands
With the exception of the frog genus Sooglossus, which diverged from Nasikabatrachus
in the K-Pg boundary with the separation between India and Seychelles, all datasets show that
the diversification of extant clades in the Western Indian Ocean islands happened in the
Cenozoic. This is no surprise as, due to the collision between India and Eurasia and the uplift
of the Himalaya in the Neogene, the sea levels fell and created much less controversial land
bridges between Africa and nearby continents. Madagascar’s unequalled endemism also has
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different origins for different taxa, but it seems to be almost as related to African taxa as to
Australian and IAA taxa: for instance, whereas the pteropodid bats reached the Comoros,
Madagascar, the Seychelles and the Mascarene islands through recent dispersal from India
(Fig. 2.2d), the chameleons colonised Madagascar at least twice from Africa – and both
dispersal events preceded further dispersal to Comoros, Eurasia and India. However, this
contradicts suggestions made by deeper studies on the origin of Malagasy biota, which have
pointed to a greater relationship to African clades (Yoder & Nowak 2006). Older studies also
proposed such affinity (Simpson 1952; Krause 2003; Krause 2010), but here we also find a
continuous invocation of land bridges to explain the colonisation of the island – even for the
relatively short distances between Africa and Madagascar. Yoder and Nowak (2006) showed
that most Malagasy taxa diverged recently, in the Cenozoic, which points to a very large
number of dispersal events, even across the Indian Ocean. Thus, the uniqueness of the fauna
of Madagascar could be due to such complex ancestry or the clades we sampled so far fail to
represent the island’s isolation. Boid snakes’ presence in Madagascar has been discussed above
and may represent a methodological failure of taxon sampling.
What our analyses consistently show is that Africa, Comoros, Madagascar, Seychelles
and the Mascarene Islands are biogeographically connected: results for all taxa show both
recent and old dispersal among these locations. Also, organisms show the same ease to travel
from east to west as in the opposite direction through the Cenozoic; even though the existence
of an east-west endemism boundary was neither evidenced nor denied by our results, we have
shown that both extremities of the Indian Ocean have an intertwined history. Among the
pteropodid bats, one particular dispersal to Africa gave rise to the Rousettinae-Epomophorinae-
Eidolon diversification. This event is interesting because groups of Eidolon helvum Kerr, 1792
are able to migrate hundreds of kilometres (Fenton 2001) and it is possible that a group co